The invention relates to a method for producing a deformation bullet, consisting of a bullet core made from lead in a tombac jacket.
The object of the invention is to provide a method for producing a deformation bullet, by which the performance of the bullet, such as accuracy, deformation and energy transfer in the target medium, can be adjusted. Moreover, a homogeneous core of the bullet should be created, the structure of which has a “predefined breaking point.”
This object is achieved by a method comprising the following method step:
a) manufacture of a cup-shaped tombac jacket, introduction of lead into the tombac jacket and soldering of the lead with the tombac jacket in order to produce a blank,
b) introduction of a pre-existing defect into the lead of the blank by pressing a die displaceable on the center axis of the blank into the lead and then removing the die, and
c) final pressing of the blank into the final shape of the deformation bullet with outer longitudinal grooves on the ogive and with a rear inner cone, wherein a pressing force larger than 7,000 N is used during the final pressing process.
The first method step (a) comprises the manufacture of a cup-shaped tombac jacket, introduction of lead into the tombac jacket and soldering of the lead with the tombac jacket in order to produce a blank. In this first method step (a), the bonded blank, consisting of a bullet core made from lead in a tombac jacket, is produced. A fixed connection is produced between the lead core or the bullet core and the tombac jacket. Bonding is always understood to mean soldering.
The second method step (b) comprises the introduction of a pre-existing defect into the lead of the blank by pressing a die displaceable on the center axis of the blank into the lead and then removing the die. By means of this pre-existing defect (parameters: depth, diameter, shape of the die), the deformation capacity of the bullet is specified. Furthermore, air inclusions, which are produced during bonding, are reduced.
The third method step (c), which can also be sub-divided into sub-steps, comprises final pressing of the blank into the final shape of the deformation bullet with outer longitudinal grooves on the ogive and with a rear inner cone, wherein a pressing force greater than 7,000 N is used during the final pressing. The flow of the lead is influenced by the pressing force exerted. The higher the force, the further the lead projects beyond the edge of the jacket. The weapon function and deformation behavior are influenced by this “lead edge.” The pressing step performed in the second method step (b) generates the pre-existing defect, as a hollow space is created in the lead core or in the bullet core. During the final pressing according to the third method step (c) this hollow space is closed again. This two-stage process produces a homogeneous bullet core, the structure of which has a predefined breaking point in the center axis of the bullet. The homogeneity is already reached at a pressing force of 7,000 N. Depending upon the pressing force (typically between 10,000 N and 30,000 N), the lead is pressed into the bullet tip to a varying extent.
In one embodiment of the invention the lead used is pure lead and a jacket of CuZn3-CuZn15 is used as the tombac jacket.
A cylindrical die with a front tip is preferably used as the die.
In an embodiment according to the invention the precision and action of the bullet are adjusted by the following parameters:
a. depth, number and length of the outer longitudinal grooves on the ogive;
b. depth, diameter and shape of the pre-existing defect;
c. pressing force during pressing of the final shape of the deformation bullet.
A rear inner cone is formed into the bullet. The selected shape of the rear of the bullet with the rear inner cone serves to optimize the pressure on the core and improves the precision of the bullet.
A deformation bullet according to the invention with a bullet core made of lead in a tombac jacket, with outer longitudinal grooves on the ogive and with a rear inner cone, produced by the method described above is characterized by a homogeneous bullet core, the structure of which has a predefined breaking point in the center axis of the bullet.
The invention is described further below with reference to the drawings.
The invention describes a bonded (soldered) deformation bullet 1, preferably 9 mm caliber, consisting of the combination of pure lead soldered in a tombac jacket (CuZn3-CuZn15). The method for manufacturing the bullet is carried out in at least three stages. The performance of the bullet, such as accuracy, deformation and energy transfer in the target medium, is adjusted by the combination of these manufacturing steps and the parameters thereof.
The first manufacturing step is the production of the bonded blank 4. A fixed connection between the lead core 9 and the tombac jacket 3 is produced by this manufacturing step.
In the second state, a “pre-existing defect” 10 is pressed into the lead core or the lead 9.
By means of this pre-existing defect 10 (parameters: depth, diameter, shape of the die) the deformation capacity of the bullet 1 is specified. Furthermore, air inclusions that are produced during bonding are reduced. Bonding is always understood to mean soldering.
In the third method step—see
The flow of the lead is influenced by the pressing force exerted. The higher the force, the further the lead projects beyond the edge of the jacket. The weapon function and deformation behavior are influenced by this “lead edge.”
The combination: a) depth, number and length of the outer longitudinal grooves 5;
Thus the invention describes a deformation bullet in which the precision and action of the bullet can be adjusted by the combination of the aforementioned three features.
The combination of different material characteristics and manufacturing steps makes it possible to produce a bullet for a defined velocity with a desired terminal ballistic action. The principle can be applied to the entire caliber range.
This possible combination system is shown by way of example on a 9 mm pistol bullet.
Bonding Process
A fixed connection between the tombac jacket 3 and the lead 9 or lead core is created by the bonding process (the soldering). The material characteristics of the tombac jacket and lead core are combined in a target-oriented manner by this connection in order to achieve an optimum target impact for the defined target velocity.
Design
In addition to the elementary material properties, by means of the variation of the jacket wall thickness it is likewise possible to influence the terminal ballistic action.
“Notches” in the ogive region also serve to control the terminal ballistic behavior.
Pre-Existing Defect and Pressing Force
The cavity inserted in the lead core (see
This also influences the target ballistics.
The deformation behavior is again influenced by means of the tucks (notches) on the bullet case in the region of the ogive.
The pressures used in the final pressing decreased in order from the bullet according to
Then by final pressing, preferably in only one pressing operation, both the ogive with the longitudinal grooves 5, or tucks (notches) and also the rear inner cone 6 are pressed.
Tail of the Bullet
The selected shape of the tail of the bullet with the rear inner cone 6 serves to optimize the pressing of the core and improves the precision of the bullet.
Influencing factors and features of the bullet according to the invention are as follows:
case wall thickness (0.2-0.5 mm depending upon caliber up to 3 mm)
case material (copper or copper alloy)
lead core (pure lead)
bonding process (heating temperature, heating time, cooling duration, fluxing agent)
pre-existing defect in the lead (depth, cross-section, shape)
notches in the ogive (number 4-8, depth 0.4-1 mm, length 1-8 mm)
hollow tip (cross-section 2-5 mm, depth 2-8 mm)
Number | Date | Country | Kind |
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10 2014 002 441 | Feb 2014 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/053853 | 2/24/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/128331 | 9/3/2015 | WO | A |
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2045964 | Rinkel | Jun 1936 | A |
5357866 | Schluckebier et al. | Oct 1994 | A |
5641937 | Carter | Jun 1997 | A |
6148731 | Winter | Nov 2000 | A |
6581503 | Olin | Jun 2003 | B1 |
20020152915 | Vaughn et al. | Oct 2002 | A1 |
Number | Date | Country |
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04426 | Jan 1899 | GB |
Entry |
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International Search Report for PCT/EP2015/053853 dated May 4, 2015; English translation submitted herewith (7 Pages). |
Number | Date | Country | |
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20160363424 A1 | Dec 2016 | US |